NO336386B1 - Security key and lock system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a safety turning key having an associated cylinder (Z), comprising a blocking groove (BN) having a coded blocking depth (B1, B2, B3) extending parallel to the key axis (x), from the key tip to at least the first position. (P1) of a pin row (A2) on the key. The assigned cylinder, at least in the rear coded position (P1), is provided with a pair of pins corresponding to one of the blocking grooves (BN), and is provided with a blocking cylinder pin (BZ) and an elongated blocking sleeve pin (BG), whereby the blocking sheath pin (BG) strikes the cylinder housing (10) when the blocking slot is too shallow and thus prevents complete insertion of the key by the blocking pair of pins. At the same time, the blocking cylinder pin (BZ) and sheath pin (BG) in position (P1) also serve as coding pins.

Description

The invention relates to a safety turnkey with an assigned cylinder according to the preamble of claim 1, a locking system with safety turnkeys for locking systems according to the preamble of claim 13, and a method for producing these according to the preamble of claim 19. Such keys and locking systems are known, where the keys with a high degree of security and a correspondingly high number of code permutations necessarily comprise at least three, preferably at least four, coding or cylinder pin puller, which is also arranged on the key's flat sides to achieve the best possible use of the available space, i.e. the given key surface, as well as the corresponding space requirement for the pin rows in the cylinder. There are also known keys with additional security elements, which again require a certain amount of space. From US 5 438 857 such a key is known with a blocking system against introduction as a further security element. Here, a further control surface is arranged on the key, which, by means of an assigned control pin at the cylinder's entrance, prevents the insertion of an incorrect key. The control pin is longer than a coding pin and extends past the midplane of the key. The control surface is arranged rising at the tip of the key, and correspondingly extends past the mid-plane of the key and lifts the control pin and thereby pushes it out of the way. As a result, the control pin prevents the insertion of keys without the proper control surface. The control surfaces may already be attached to the key workpiece and thus enable protection of the workpiece.

These known high-security keys and systems with high-security keys are always limited by the available space for the coding and security functions on the key and in the cylinder. Their manufacture requires a central production, which limits, complicates and delays the universal application of such systems worldwide. An optimal construction for installation and use of any type is thereby severely limited. The task of the present invention is therefore to provide a safety turning key with an assigned cylinder, resp. a locking system with reversible security keys and associated cylinders, which will be able to be used worldwide as a unique locking system with a higher permutation capacity for any type of application, with increased security and protection against copying, as well as with new possibilities to be able to to single out any type of market area and application throughout the world, whereby, without additional space requirements on keys and in cylinders, higher security and a greater number of permutations are achieved. As a further aim, a method for the production of such a system is sought, which will be able to be quickly and universally put into use and used all over the world.

According to the invention, this purpose is achieved by means of a safety turnkey with an assigned cylinder according to claim 1, by means of a locking system with safety turnkeys with assigned cylinders according to claim 13, as well as by means of a method for producing such keys according to claim 19. With the new additional security element "blocking code", which comprises a coded blocking slot and an assigned pair of blocking pins, without any further requirement for space on the key and in the cylinder, i.e. with the existing coding positions on the key and the existing pin pullers and positions in the cylinder, a further insertion blocking system is achieved as well as a higher number of permutations and applications. By the division into areas on the key, whereby the first area with additional security elements defines a clear segmentation into independent market areas, a system has been provided which corresponds to the above-mentioned purpose and which can be realized with the new multi-stage manufacturing process.

The non-independent claims relate to advantageous further developments of the invention, which enable further advantages in terms of universal applicability, the possibility of rapid production worldwide, the security of a locking system, security against copying, the number of permutations and applications.

In particular, with the new additional security element "blocking code", which consists of a coded blocking slot and an assigned pair of blocking cylinder pins, without any additional space requirements on the key and in the cylinder, i.e. with the existing coding positions on the key and - positions in the cylinder, it has been achieved an additional insertion-blocking system, as well as a higher number of permutations and applications.

In the following, the invention will be explained in more detail on the basis of examples of embodiments with reference to the attached drawings, where

fig. la shows coding rows with coding positions for two drilling patterns on one key,

fig. lb shows a division of the key into areas, with a first area containing additional security elements,

fig. lc is a further example of division into areas,

fig. Id shows a segmentation of market areas and distributor areas on a key,

fig. le shows a connection between division into areas and segmentation of market areas,

fig. 2 shows the principle of the blocking code with blocking slots and blocking pin pairs,

fig. 3 shows examples of coding steps and blocking steps,

fig. 4 shows examples of different forms of staples,

fig. 5 shows shapes of blocking tracks corresponding to fig. 4,

fig. 6 shows coding forms corresponding to fig. 4,

fig. 7 shows a blocking track extending over four positions with different areas,

fig. 8 is a three-dimensional representation of an interlocking slot with an interlocking pair of cylinder pins,

fig. 9 are three-dimensional representations of various examples of block tracks with coding positions (corresponding to the examples of Fig. 14),

fig. 10 shows a safety element "insertion blocking" by means of a control surface and a control pin,

fig. 11 shows a safety element "flat pin" for edge control of the encodings,

fig. 12 shows a key with four rows of pins and with blocking pins in the cylinder,

fig. 13 shows examples of keys with five and with eight coding resp. cylinder pin puller,

fig. 14 is a locking function core with two drilling patterns and two market areas,

fig. 15 is a locking function core with two positions and four market areas,

fig. 16 is a locking function core with two positions and one market area,

fig. 17 is a locking function core with one position in each of two pin pulls and with three market areas,

fig. 18 is an organizational chart for a locking system with segmented market areas and applications, and

fig. 19 is a manufacturing diagram for keys in a locking system according to the invention.

As an example, fig. let a safety turnkey S with four pin pullers Al - A4 and with 22 coding positions Pi, each for a drilling pattern L on the left, and a drilling pattern R on the right. The coding row A2 on the key S here has the positions RI - R5 for the drilling pattern R and the positions L6 - LII for the drilling pattern L. On the keys, all positions for both drilling patterns can be coded, i.e. there are keys with a drilling pattern on the right and also keys with the two drilling patterns R + L. In the assigned cylinder Z, however, due to space for the pins, only every other position, and for these only either a bore pattern R or a bore pattern L, can be supplied with cylinder pins (in the same area ). The first coding position Pl (=L11) on the tip of the key corresponds here to the rearmost pin position Pl in the cylinder as regards

the key's insertion direction x.

Fig. 1b shows the locking system according to the invention with a key S, where at least two areas are defined on the key, where in a first area Gl there are arranged at least two further security elements with a higher

degree of difficulty to produce, and a simpler basic coding, Codl, is arranged in a second area G2, while in the first area Gl a clear segmentation is defined in independent market areas Mi = Ml, M2 etc. Here also

shown further safety elements, which are more precisely defined in the following: a blocking code BC, a second coding Cod2, preferably with a narrower milling, an insertion-blocking system by means of a control surface and control pin KF/KS and a flank control of Cod2 by using a flat pin 23. The simple basic coding Codl is e.g.

a coding using drills, which are relatively easy to carry out decentralized anywhere.

Fig. 1c shows another division into areas, whereby the area Gl can be divided into several sub-areas Gl.l, Gl.2 etc. Depending on the application and the desired system design,

can e.g. the area Gl also comprise a whole coding sequence A2. By doing it this way, all security elements are also arranged in this one coding row. In another advantageous variant, parts of areas of two coding rows (Al, A2) with positions right at the front end of the key

could form the area Gl, whereby e.g. both parts of the areas Gl.l, Gl.2 will each be provided with a blocking code BC.

Fig. Id shows the division into several independent market areas Mi = Ml, M2 etc, as well as the possible further one

division of each market area into parts of market areas MMi, e.g. in independent distributor areas, or application areas for installations and objects etc. The market areas Mi are defined by the area Gl. The parts of the areas MMi can be defined by parts of the area Gl,

or also at parts of the area G2, or they could just as well include parts of the areas Gl and G2.

Fig. 1e shows e.g. a connection between the areas Gl, G2 of the key and the unique separation in the market area Mi, parts of the market areas MMi, as well as the further division for objects MMi.i. This will be further described in the description of fig. 18.

Preferably, the area Gl comprises at least three security elements Vi. Particularly important and advantageous is the new additional security element "blocking code". In the case of the blocking code BC as a further coding and security function according to the invention, as explained in connection with fig. 2, coding position Pl and its function on key S and cylinder Z are maintained.

Fig. 2 schematically shows the way the blocking code BC according to the invention functions on a key S and an assigned cylinder Z. The directions in space are denoted in the following by x, y, z, and x is the key or the cylinder axis. One

blocking track BN, which runs parallel to the key axis x and which extends at least to the first codeine position Pl, is arranged on, resp. milled into, key-len. Correspondingly, in the assigned cylinder, at least at the rearmost coding position Pl, a pair of blocking pins are arranged, with a spring-loaded blocking cylinder pin BZ and an extended blocking jacket pin BG. The blocking groove has a coded blocking depth Bl, B2, B3, and accordingly the length lb of the pair of blocking pins (BZ + BG) is coded in such a way that lb corresponds to the distance db of the blocking groove BN from the cylinder housing 10, i.e. the pair of blocking cylinder pins (or the pair of blocking pins) fit into the blocking groove with little clearance. When inserting the key, the following sequence results: (a - b - c): The blocking cylinder pin BZ is lifted by a chamfered insertion surface 6 on the key up to the level of the blocking groove BN and passes with little clearance to the cylinder housing 10 through the blocking groove up to the corresponding coding position Pl, whereby the blocking cylinder pin BZ is lowered to the first coding position with a certain coding step, here e.g. C2. In this position Pl, the pair of blocking cylinder/mantle pins BZ, BG functions as a normal coding position when it comes to turning the cylinder, which in case of correct coding will have to release the cutting line 9. If the blocking groove BN is not deep enough, resp. if it has the wrong coding Bi, the blocking mantel pin BG abuts the cylinder housing 10 and further insertion of the key is blocked by the chamfered insertion surface (if lb is greater than db, ref. fig. 8a). The blocking code therefore results in a further security function in that complete introduction will be prevented with further coding step Bi in the blocking slot, whereby the coding function hitherto at position Pl

be justified. In addition to this, no additional space for the blocking code will be required either on the key, i.e. on the key positions, or in the cylinder. In the cylinder, a until now common coding pin is replaced with the special blocking pin. Fig. 3 shows possible blocking stages Bi with a depth tb compared to the coding stages Ci with the coding depths tc in relation to the key surface. In the following examples, coding steps Cl - C4 (e.g. steps of 0.35 mm) as well as three blocking steps Bl, B2, B3 with blocking depths of e.g. 1.05, 0.55 and 0 mm, where a blocking step B3 with a depth of 0 mm will no longer be able to exercise a blocking function. The blocking depths Bi can also correspond to the coding depths Ci, i.e. e.g. Cl - C4 and Bl - B4. In a further example, five coding steps C1 - C5 are shown in combination with four blocking steps B1 - B4, e.g. with a step distance of 0.3 mm for Ci and 0.4 mm for Bi. In accordance with the rule of the combination between the blocking steps Bi and the coding steps Ci, the coding depth tc of the coding steps Ci must not be less than the blocking depth tb of the preceding blocking track Bi. In this example, the blocking step B3 can therefore be combined with the subsequent coding steps C3, C2 or Cl. Figs. 4, 5 and 6 show different possible pin shapes (Fig. 4a, b, c) assigned shapes of the blocking grooves BN (Fig. 5a, b, c) as well as the coding shapes assigned to the pins (Fig. 6a, b, c). Fig. 4a shows a conventional conical holder pin shape 21, e.g. for a basic coding Codl, which will be able to be produced using simple drilling (fig. 6a). Fig. 4b shows a narrow cylindrical pin shape 22 with correspondingly narrow coding grooves (Fig. 6b), the manufacture of which e.g. requires a laborious milling process that is difficult to copy and which e.g. will be able to be used as a second coding Cod2. Fig. 4c shows a flat pin 23, which e.g. can be used for the edge control of a narrow milled coding (fig. 6c), which will be explained in more detail later. Also further shapes of pins, which are in principle a combination of cylindrical and conical sections, are possible and known. The block track forms and the coding forms can be used differently and as a result make any copying more difficult and also cause a further camouflage of the coding forms. Fig. 7a, b, c shows an example of a blocking track which extends over the four front coding positions Pi = LII, R5, L10 and R4 of two drilling patterns R, L and which correspondingly has several differently coded sectors BN1 - BN4, whereby the as a rule, care must be taken that the depth tb of the blocking grooves remains the same from one position to the next position, or less (ie cannot become larger) and that likewise the width bb of the blocking grooves remains the same from one position to the next , or becomes smaller. In connection with three blocking steps Bl - B3 and two blocking track widths bbl and bb2, this results in the shown blocking steps Bi, bbi of the four blocking track sections BN1 - BN4. Fig. 8 shows three-dimensionally the function of the blocking code, and Fig. 9 block track forms and the adjacent coding recesses, which correspond to the example of fig. 14. In fig. 8a, b shows a key Sla with a blocking slot provided with a blocking step B2 and with adjacent coding positions LII and R5 provided with codings Cl and C2 (corresponding to key Sla in Fig. 14). Fig. 8a shows a pair of blocking cylinder/jacket pins BZ, BG with blocking code Bl, the length of which is greater than the distance db of the blocking groove from the cylinder housing 10. By means of this, a complete introduction of the key Sla into this cylinder is blocked. Fig. 8b, on the other hand, shows a pair of blocking cylinder/jacket pins BZ, BG with a blocking code B2, which corresponds to the blocking code B2 of the blocking slot BN and therefore enables complete

introduction. In the schematic diagram in fig. 14 corresponds to this key Sla which opens the cylinder Zl (with coding Cl at this position R5).

Fig. 9a - 9d show the keys S1, S2, S3 and S1a with differently coded blocking slots and positions LII and R5. This also corresponds to the schematic locking diagram in fig. 14, which indicates which key/cylinder combinations open

and which ones are blocking.

As a possible additional safety element, fig. 10 a known per se blocking system against insertion by means of a control surface KF at the tip of the key, and an assigned control pin KS in the cylinder. This control surface KF extends past the middle plane 5 of the key, just as the control pin KS which hits the rising control surface KF will have to be pushed out of the way by this in order for the key to be inserted. A key without the correct control surface, resp. with only normal insertion surfaces 6, abuts with its tip against this control pin KS, so that it prevents insertion of the key. This is a completely different arrangement and operation than according to the blocking code according to the invention, which does not require any special control surfaces, but rather works with any existing key insertion surface 6. Advantageously, however, the new blocking code down the blocking pins BZ can be combined with this known insertion blocking by means of control surfaces KF and the control pin KS, and especially even be assigned in the same row of pins (eg A2), whereby the control pin KS is positioned anywhere in front of the pair of blocking pins BZ, BG in the cylinder.

An important additional safety element, which can also be assigned in the same series of pins, is shown in fig. Ila, 11b. These show a flank control with a narrow coding milling Cod2, which is performed by a flat holding pin 23. The flat holding pin 23 (cf. e.g. Fig. 4c) has a diameter d2 that is greater than the width dl of the coding milling, so that the flat pin rests on the key surface 7, as shown in fig. Ila. In the case of a base coding Codl, e.g. according to fig. 6a, on the other hand, the flat pin 23, with sufficiently wide bores d3, will sink into these recesses in accordance with fig. 11b, whereby the cutting line 9 of the cylinder is blocked. Thus, e.g. a simple forged bore, instead of the approved, much more cumbersome narrow coding milling Cod2, could be detected, thus preventing the forged key from working.

Therefore, the following very effective safety elements can be combined appropriately in a small space and in a single row of pins: in addition to the blocking code BC according to the invention, a second coding Cod2 with narrow milling, an insertion control by means of a control pin KS and the control surface KS, so as well as a flank control of the narrow coding Cod2 by means of a flat pin 23.

Fig. 12 shows a cross-section of a rotatable security key with four pin pullers A1 - A4 in a cylinder according to the example in fig. 1. The row Al is here provided with a narrow coding milling Cod2 and a pair of blocking cylinder/mantle pins BZ, BG. Rows A3 and A4 (and possibly also row A2) are here provided with a simpler basic coding Codl. It is important to utilize the given key surface and the space in the cylinder in the best possible way for coding positions and security elements. To achieve this, necessarily (at least two) rows of pins will also have to be placed on the flat sides of the key. In the case of slightly larger keys, it will also be possible to arrange more than four rows of pins.

For this purpose, fig. 13a an example with five pin pullers A1 - A5, and fig. 13b an example with eight pin pullers Al - A8, which, however, will only be able to be supplied with pins in the cylinder to such an extent that there is available space. However, thanks to the use of narrow encodings, it is also possible here to encode all eight rows on the key. This results in a large number of possible permutations as well as additional safety reserves. In principle, it will also be possible to arrange a blocking coding at the beginning of each row Al of pins.

In fig. 14 - 17 schematically show locking function diagrams with different combinations of blocking codes Bi and codings Ci of the adjacent positions Pi. In the left column, the codings Bi, Ci of the keys Si are indicated, and in the row at the top the codings of the cylinders Zi. The keys can have the drill patterns R or L or R + L (both), while the cylinders will only be able to contain one drill pattern R or L. The schematic diagram indicates with an "X" if a combination key/cylinder fits, i.e. if the key opens the corresponding cylinder. All other combinations block. Fig. 14 - 17 show how with few blocking codings Bi and adjacent position codings Ci it will be possible to clearly distinguish between different market areas Mi, and how within a market area it will be possible to carry out several derivations, i.e. hierarchical differentiations, of keys in a installation.

The schematic diagram in fig. 14 (corresponding to Figs. 8 and 9) shows codings Ci with two drilling patterns and with two positions

P1 = LII and P2 = R5

with five equipment options with blocking steps Bi = Bl, B2, B3 of the blocking slots and coding steps Ci = Cl and C2. Thereby, two independent market areas Ml, M2 are defined, each defined by three, resp. two derivations.

The key S3 opens e.g. cylinders Zl and Z3.

Fig. 15 shows only one drilling pattern L with blocking code over two positions

P1 = LII and P2 = L10

with blocking steps Bl, B2, B3

and with coding steps Cl, C2.

Thereby, four independent market areas Ml - M4 are defined, each with three derivations.

The key Sllabc opens e.g. cylinders Zlla, Zllb, Zllc.

Fig. 16 shows a drilling pattern L with two positions P1 = LII and P2 = L10

with blocking code Bl, B2, B3

and coding stage LII = Cl and L10 = Cl,

whereby five diversions are created at the blocking steps within a market area.

That is key Sllabcde opens the five cylinders Zlla - Zlle

and key Sila only opens cylinder Zlla.

Fig. 17 shows an example with only one position Pi, each however in two rows of pins A1, A2. Both positions Pl are coded with Cl,

while with the blocking steps B1, B2, B3 of the blocking tracks, three independent market areas M1, M2 and M3 are defined.

The key Sl only opens cylinder Zl, S2 only opens Z2, and S3 only opens Z3. Fig. 18 shows an organization of the locking system according to the invention with reversible security keys in a hierarchical schematic diagram. The system owner SS (e.g. a production company) represents the highest hierarchical level, which defines and authorizes the market areas Mi = Ml, M2 etc., where a market area e.g. can be a country or a main distributor. In the market areas, further parts of areas Mmi are defined and separated, e.g. for different distributors or installations within the area. A further level Mmi.i can define individual objects. This is defined by the coding of the areas G1 and G2. Fig. 19 schematically shows a manufacturing method for keys for a system according to the invention, with manufacturing stage H, areas G on the key and with the manufactured variables Vi in the areas G. In general, the manufacturing H with reducing degree of difficulty HS takes place at lower levels, resp. decentralized.

The variables We and security elements such as e.g. is produced in the different areas Gi and in the corresponding production steps are also indicated in the table.

When manufacturing keys and cylinders for a locking system with at least two areas Gl, G2, first the first area of the keys is produced or checked and approved at a central production site Hl, and the coding Codl of the keys of the other area G2 and the equipping of the cylinders with corresponding pins will then be able to take place at a local representative H2.

The production can take place in at least two stages, resp. in different places, where the first variables with the highest degree of difficulty HS of the area Gl are produced in a central place, and subsequent variables with a lower degree of difficulty of the area G2 are produced decentralized or locally.

The production of the keys will also be able to take place in three stages, where first the first area Gl with variable Vi with the highest degree of difficulty is produced centrally; Hl; then a further area Gl/2 is produced with variables of lower regional difficulty: Hl/2; and finally, the coding with the lowest degree of difficulty is produced by the area G2 at the application site H2.

In the event of a further development of the system, the preparation of the area Gl will also be able to take place in a decentralized manner.

To implement this, manufacturing programs and the authorization "aut" must be able to be managed and controlled from the central place SS (system owner).

With the system according to the invention and the production methods, a universal differentiation of market areas and parts of market areas, as well as a rapid local production is made possible.

Within the framework of this presentation, the following designations are used;

Claims (22)

1. Safety turning key with at least three rows (A1, A2, A3) of coding pins/holder pins, which are also arranged on the flat sides of the key (S), with an associated cylinder (Z) with pin puller of pairs of cylinder pins consisting of cylinder pins and mantle pins at the positions of the pin rows of a given drilling pattern, characterized in that the key is provided with a blocking groove (BN) which runs parallel to the key axis (x), from the tip of the key to at least the first position (Pl) of a pin row on the key, that the blocking groove is provided with a coded blocking depth (Bl, B2, B3), that in the assigned cylinder, at least at the rearmost coding position (Pl), a pair of pins corresponding to the blocking groove (BN) is arranged, i.e. a blocking cylinder pin (BZ) and an extended blocking jacket pin (BG), so that the blocking jacket pin hits the cylinder housing (10) if the blocking groove is not deep enough, whereby the introduction of a key with an unstressed The deep blocking groove is blocked by means of a pair of blocking cylinder pins, whereby the blocking cylinder pin (BZ), with the blocking mantle pin (BG), after the introduction of the key at the position (Pl), is also used as a coding pin with coding steps (Cl, C2 , C3, C4) in terms of the rotation of the cylinder. 2. Key according to claim 1, characterized in that at least four rows of staples (Al - A4) are arranged. 3. Key according to claim 1, characterized in that at least two different codings (Cod1, Cod2) are provided. 4. Key according to claim 1, characterized in that coding positions (Pi) from two different drilling patterns (R, L) are arranged. 5. Key according to claim 1, characterized by blocking grooves which extend to at least the two positions (P1, P2) at the very beginning of a coding row (A2), and by blocking cylinder pins (BZ1, BZ2) and blocking jacket pins (BG1, BG2) which correspond to these positions, and at coded step depths of these at least two positions at the very beginning. 6. Key according to claim 1, characterized in that the blocking track comprises at least two differently designed sectors (BN1, BN2). 7. Key according to claim 1, characterized in that the blocking track extends over more than one coding position, and that the depth (tb) of the blocking track remains the same from one position (Pl) to the next position (P2), or becomes smaller. 8. Key according to claim 1, characterized in that the blocking track extends over more than one coding position, and that the width (bb) of the blocking track remains the same from one position (Pl) to the next position (P2), or becomes narrower. 9. Key according to claim 1, characterized in that by more than one row of pins (A1, A2), each is provided with a blocking slot with associated pairs of pins. 10. Key according to claim 1, characterized in that, as a further safety element, a rising control surface (KF) is placed at the tip of the key, which pushes an assigned control pin (KS) out of the way, whereby the control pin (KS) prevents the introduction of a key without a control surface (KF). 11. Key according to claim 10, characterized in that the control pin (KS) is designed as a flat pin (23), which also carries out a flank control by means of a narrow coding milling (Cod2). 12. Key according to claim 1, characterized in that the following security elements are arranged in a row of pins (A2): blocking code (BC), second coding (Cod2), insertion blocking system by means of a control surface (KF) and control pin (KS), as well as edge control by means of a flat pin (23). 13. Locking system with safety turning key for locking systems, with at least three rows (A1, A2, A3) of coding pins/holding pins, which are also arranged on the flat sides of the keys (S), with associated cylinders (Z) with pin pullers of pairs of pins, consisting of cylinder pins and casing pins at the positions of a given drilling pattern, and with at least two additional safety elements, characterized in that at least two areas of the keys are defined, where in a first area (G1) at least two additional security elements with a higher degree of manufacturing difficulty are arranged, and in the second area (G2) a simpler base coding is arranged (Codl), and where an unambiguous segmentation into independent market areas (Ml, M2 ...) is defined in the first area (Gl), and where the first area (Gl), as a further security element, is provided with a blocking code (BC), i.e. the keys are provided with a blocking groove (BN) which runs parallel to the axis (x) of the key, from the tip of the key to at least the first position (Pl) of a row of pins on the key, where the blocking groove has a coded blocking depth (Bl, B2, B3), where in the assigned cylinder, at least at the rearmost coding position (Pl), a pair of pins is arranged, i.e. a blocking cylinder pin (BZ) and an extended blocking jacket pin (BG) which corresponds to blocking spo ret (BN), so that the blocking jacket pin (BG) hits the cylinder housing (10) if the blocking slot is not deep enough, why complete insertion of a key with an insufficiently deep blocking slot is blocked by the pair of blocking pins, and where the blocking cylinder pin (BZ) and the blocking mantel pin (BG), after the introduction of the key to the position (Pl), are also used as a coding pin with coding steps (Cl, C2, C3, C4) when it comes to turning the cylinder. 14. Locking system according to claim 13, characterized in that a second coding (Cod2) is arranged as security elements in the first area (Gl), an insertion block by means of control surfaces (KF) on the key and the assigned control pin (KS) in the cylinder, a flank control using a flat pin (23) and a blocking code (BC). 15. Locking system according to claim 13, characterized in that different drilling patterns (R, L) are arranged in areas on the key. 16. Locking system according to claim 13, characterized in that at least three security elements are arranged in the first area (Gl). 17. Locking system according to claim 13, characterized in that a second coding (Cod2) with narrow milling is arranged as a security element. 18. Locking system according to claim 13, characterized in that all security elements for the area (G1) are arranged in one coding row (A2). 19. Method for manufacturing keys and cylinders of a locking system with at least two areas (Gl, G2) on the keys (S) according to claim 13, characterized in that first the first area (Gl) is produced on the keys, resp. is checked and approved at a central manufacturing site (Hl), and that the coding (Codl) of the keys' second area (G2) and the fitting of the cylinders with corresponding pins then takes place decentralized with a local representative (H2). 20. Method according to claim 19, characterized in that the production takes place in at least two steps, resp. in different places, where the first variable (Vi) with a higher degree of difficulty (HS) of the area (Gl) is produced in a central place, and that variables with a lower degree of difficulty of the area (G2) are then produced decentralized or locally. 21. Method according to claim 19, characterized in that the production of the keys takes place in at least three stages, where first the first area (Gl) with variable (Vi) with the highest degree of difficulty is produced centrally (Hl), then a further area (Gl/ 2) with variables with a lower degree of difficulty are produced regionally (Hl/2), and finally the coding with the lowest degree of difficulty of the area (G2) is produced locally at the place of use (H2). 22. Method according to claim 19, characterized in that the production of the area (Gl) will also be able to take place decentralized, whereby the production programs and the authorization (aut) for this are managed and controlled from a central location (SS).